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Determining the biomass energy potential derived from agricultural wastes in Uganda

Year 2024, Volume: 9 Issue: 4, 943 - 955, 25.12.2024
https://doi.org/10.58559/ijes.1523321

Abstract

Biomass energy derived from agricultural residues holds significant potential for addressing energy needs in Uganda. As a country heavily reliant on traditional biomass sources, the utilization of agricultural waste, such as crop residues, offers a sustainable and renewable energy alternative. This study explores the availability, energy potential, and environmental benefits of using agricultural residues for biomass energy production in Uganda. By analyzing various types of residues, including maize stalks, rice straw, and potatoes stalks, the energy yield was estimated. The findings highlight the potential of agricultural residues to contribute significantly to Uganda's energy supply while reducing environmental degradation associated with conventional biomass use. The amount of agricultural residues produced from annual crops cultivated in Uganda, measured in tons of dry matter per year, was determined using agricultural production data from the Food and Agriculture Organization Statistical Database of the United Nations (FAOSTAT) for the year 2021. The annual gross potential of agricultural residues was calculated by applying the residue-to-product ratio. The total amount of agricultural wastes in Uganda, encompassing annual crop residues such as barley, maize (corn), millet, potatoes, rice, sorghum, soya beans, and wheat was calculated to be approximately 24.9 Kt. The primary crops contributing to the overall residue quantity ratio are maize (59.52%), beans (13.65%), rice (10.53%), sorghum (8.76%), and soya beans (3.85%). Uganda has a significant supply of raw materials suitable for energy production from agricultural residues. For the 2021 production period, the total energy potential of these residues was estimated to be around 432.1 TJ.

References

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Year 2024, Volume: 9 Issue: 4, 943 - 955, 25.12.2024
https://doi.org/10.58559/ijes.1523321

Abstract

References

  • [1] Wanyama J, Nakawuka P, Bwambale E, Kiraga S, Kiggundu N, Barasa B, Katimbo A. Evaluation of land suitability for surface irrigation under changing climate in a tropical setting of Uganda, East Africa. Agricultural Systems 2024;217:103937.
  • [2] El Hafdaoui H, Jelti F, Khallaayoun A, Jamil A, Ouazzani K. Energy and environmental evaluation of alternative fuel vehicles in Maghreb countries. Innovation and Green Development, 2024; 3(1): 100092
  • [3] Farida KAFI, Hanene AMROUCI, Bilal NECIRA. Energy security and diversification of energy resources are imperative for building a new model of development in Algeria 2024;9(1):122–139.
  • [4] Ayik A, Ijumba N, Kabiri C, Goffin P. Selection of off-grid renewable energy systems using analytic hierarchy process: case of South Sudan. In: 2020 IEEE PES/IAS PowerAfrica. IEEE, 2020;1-5.
  • [5] Demirel B, Alp G, Gürdil K, Gadalla O. Biomass energy potential from agricultural production in Sudan. ETHABD 2019;2(2):35-38
  • [6] Evans O. The investment dynamics in renewable energy transition in Africa: The asymmetric role of oil prices, economic growth and ICT. International Journal of Energy Sector Management 2024;18(2): 229-247.
  • [7] Tiar B, Fadlallah SO, Benhadji Serradj DE, Graham P, Aagela H. Navigating Algeria towards a sustainable green hydrogen future to empower North Africa and Europe's clean hydrogen transition. International Journal of Hydrogen Energy 2024; 61: 783-802.
  • [8] Bergougui B. Moving toward environmental mitigation in Algeria: Asymmetric impact of fossil fuel energy, renewable energy and technological innovation on CO2 emissions. Energy Strategy Reviews 2024;51: 101281.
  • [9] Maradin D. Advantages and disadvantages of renewable energy sources utilization. International Journal of Energy Economics and Policy 2021;11(3):176-183.
  • [10] Zhang H, Jing Z, Ali S, Asghar M, Kong Y. Renewable energy and natural resource protection: Unveiling the nexus in developing economies. Journal of Environmental Management 2024; 349: 119546.
  • [11] Aicha M. Developing Renewable Energies as an Economic Alternative in Light of Achieving Sustainable Development in Algeria Abstract : Developing Renewable Energies as an Economic Alternative in Light of Achieving Sustainable Development in Algeria 2024;8:937–950.
  • [12] Karaca C, Kağan Gürdil GA, Ozturk HH. The biomass energy potential from agricultural production in the Black Sea Region of Turkey. In: ICOEST 3rd International Conference on Environmental Science and Technology, 19-23 October, Budapest, Hungary. 2017; 184-189.
  • [13] Kaweesa S, Mkomwa S, Loiskandl W. Adoption of conservation agriculture in Uganda: A case study of the Lango subregion. Sustainability 2018; 10(10): 3375.
  • [14] Zizinga A, Mwanjalolo JGM, Tietjen B, Martins MA, Bedadi B. Maize yield under a changing climate in Uganda: long-term impacts for climate smart agriculture. Regional Environmental Change 2024; 24(1): 34.
  • [15] Karaca C, Gürdil GAK, Öztürk HH. Determining and mapping agricultural biomass energy potential in Samsun Province of Turkey. In: ICOEST 3rd International Conference on Environmental Science and Technology 2017;34-43
  • [16] ASTM. ASTM D5865-02 | PIP Store. 2002. (accessed Nov. 25, 2024).
  • [17] Karaca C. Mapping of energy potential through annual crop residues in Turkey. International Journal of Agricultural and Biological Engineering 2015; 8(2): 104-109.
  • [18] FAOSTAT. 2021.https://www.fao.org/faostat/en/#data/GCE (accessed May 07, 2024).
  • [19] Eissa MOS, Gürdil GAK, Ghanem L, Demirel B. Biomass Energy Potential from Agricultural Production in Libya. Tarım Makinaları Bilimi Dergisi 2024; 20(2): 61-71
  • [20] Ghanem L, Gürdil GAK, Omer Salih Eissa M, Demirel B. Determining and Mapping Biomass Energy Potential from Agricultural Residues in Syria. Black Sea Journal of Agriculture 2024; 7(4): 391-398.
There are 20 citations in total.

Details

Primary Language English
Subjects Biomass Energy Systems
Journal Section Research Article
Authors

Mohamedeltayib Omer Salih Eissa 0000-0003-0186-1112

Publication Date December 25, 2024
Submission Date July 27, 2024
Acceptance Date November 27, 2024
Published in Issue Year 2024 Volume: 9 Issue: 4

Cite

APA Omer Salih Eissa, M. (2024). Determining the biomass energy potential derived from agricultural wastes in Uganda. International Journal of Energy Studies, 9(4), 943-955. https://doi.org/10.58559/ijes.1523321
AMA Omer Salih Eissa M. Determining the biomass energy potential derived from agricultural wastes in Uganda. Int J Energy Studies. December 2024;9(4):943-955. doi:10.58559/ijes.1523321
Chicago Omer Salih Eissa, Mohamedeltayib. “Determining the Biomass Energy Potential Derived from Agricultural Wastes in Uganda”. International Journal of Energy Studies 9, no. 4 (December 2024): 943-55. https://doi.org/10.58559/ijes.1523321.
EndNote Omer Salih Eissa M (December 1, 2024) Determining the biomass energy potential derived from agricultural wastes in Uganda. International Journal of Energy Studies 9 4 943–955.
IEEE M. Omer Salih Eissa, “Determining the biomass energy potential derived from agricultural wastes in Uganda”, Int J Energy Studies, vol. 9, no. 4, pp. 943–955, 2024, doi: 10.58559/ijes.1523321.
ISNAD Omer Salih Eissa, Mohamedeltayib. “Determining the Biomass Energy Potential Derived from Agricultural Wastes in Uganda”. International Journal of Energy Studies 9/4 (December 2024), 943-955. https://doi.org/10.58559/ijes.1523321.
JAMA Omer Salih Eissa M. Determining the biomass energy potential derived from agricultural wastes in Uganda. Int J Energy Studies. 2024;9:943–955.
MLA Omer Salih Eissa, Mohamedeltayib. “Determining the Biomass Energy Potential Derived from Agricultural Wastes in Uganda”. International Journal of Energy Studies, vol. 9, no. 4, 2024, pp. 943-55, doi:10.58559/ijes.1523321.
Vancouver Omer Salih Eissa M. Determining the biomass energy potential derived from agricultural wastes in Uganda. Int J Energy Studies. 2024;9(4):943-55.